Rotary valve component means

ABSTRACT

Rotary valve component means having a rotary valve face disposed to sealingly engage face wall valve means having communicating fluid port means therein to control the flow of fluid to and from fluid pressure operating means. The rotary valve component means is reversible in operation and has a hollow annular valve body for retaining fluid externally therearound and for retaining fluid internally therewithin to provide for said reversible operation. The hollow annular valve body has a valve end portion comprising an external flange body extending outwardly therefrom and an internal flange body extending inwardly therefrom. The external and internal flange bodies respectively have inside and outside flange faces. The rotary valve face includes the outside flange faces. The inside flange faces constitute fluid retaining faces to blank flow of fluid to and from said face wall valve means. The external flange body has external fluid conduction wall means communicatingly interconnecting said inside and outside external flange faces and has internal fluid conduction wall means communicatingly interconnecting said inside and outside internal flange faces. The external and internal fluid conduction means communicatingly register with the fluid port means in the face wall valve means.

United States Patent 1191 Woodling 1 1 Feb. 6, 1973 1 ROTARY VALVE COMPONENT MEANS George V. Woodling, 22077 West Lake Road, Rocky River, Ohio 44116 [22] Filed: Feb. 24, 1971 [21] Appl. No.: 118,312

[76] Inventor:

Related U.S. Application Data [63] Continuation of Ser. No. 887,614, Dec. 23, 1969, Pat. No. 3,591,321, which is a continuation of Ser. No. 637,382, May 10, 1967, Pat. No. 3,405,603.

Primary Examiner-William L. Freeh Assistant Examiner-John J. Vrablik Att0rneyW0odling, Krost, Granger & Rust 1 5 7 1 ABSTRACT Rotary valve component means having a rotary valve face disposed to sealingly engage face wall valve means having communicating fluid port means therein to control the flow of fluid to and from fluid pressure operating means. The rotary valve component means is reversible in operation and has a hollow annular valve body for retaining fluid externally therearound and for retaining fluid internally therewithin to provide for said reversible operation. The hollow annular valve body has a valve end portion comprising an external flange body extending outwardly therefrom and an internal flange body extending inwardly therefrom. The external and internal flange bodies respectively have inside and outside flange faces. The rotary valve face includes the outside flange faces. The inside flange faces constitute fluid retaining faces to blank flow of fluid to and from said face wall valve means. The external flange body has external fluid conduction wall means communicatlngly interconnecting said inside and outside external flange faces and has internal fluid conduction wall means communicatingly interconnecting said inside and outside internal flange faces. The external and internal fluid conduction means communicatingly register with the fluid port means in the face wall valve means.

9 Claims, 31 Drawing Figures PATENTEDFEB 6l975 I 3,715,175

FIG.2

3 0 Q Q 0 i INVENTOR.

GEORGE V. WOODLING BY PATENTEDFEB ems 3.715175 SHEET 20F 4 FIG.3

INVENTOR.

GEORGE V. WOODLING M,MW

4 2| FIG.4 20 2 FIGS 20 PATENTEDFEB 6mm 3.715175 SHEET 30? 4 FIG-I4 FIG. l7 IG.I3

INVENTOR.

GEORGE V. WOODLING BY I02 FIG.I5 loz FIG.I6 FIG.I8 FIGJQ PAIENTEDFEB s [975 3,715,175

, sum u or 4 FIG. 22

INVENTOR.

GEORGE V. WOODLING BY FIG.29 FIG.3O FIG.3I "B" M M ROTARY VALVE COMPONENT MEANS BACKGROUND OF THE INVENTION This application is a continuing application of my pending application, Ser. No. 887,614, filed Dec. 23, 1969, now U.S. Pat. No. 3,591,321 the latter being characterized as a second continuation of my prior application, Ser. No. 637,382, filed May 10, 1967, now US. Pat. No. 3,405,603.

Rotary valve component means which sealingly engage face wall valve means to commutatively control the flow of fluid therethrough, have many configurations and porting, all being deficient in performance, unsymmetrical in construction, or non-reversible in operation.

Accordingly, it is an object of my invention to provide commutative valving of .a symmetrical construction.

Another object of my invention is to provide commutative valving which is reversible in operation.

Another object is to provide commutative valving with open slots, whereby the mutually engaging valve faces are self-cleaning, in that foreign particles which may become lodged between the engaging valve faces have an opportunity to become discharged through the open slots.

SUMMARY OF THE INVENTION This invention constitutes rotary valve component means having a rotary valve face disposed to sealingly engage face wall valve means having communicating fluid port means therein, said rotary valve component means including hollow annular valve body means having a valve end portion, said hollow annular valve body means retaining fluid externally therearound and retaining fluid internally therewithin, said valve end portion having external flange body means extending outwardly of said hollow annular valve body means and internal flange body means extending inwardly of said hollow annular valve body means, said external and internal flange body means respectively having inside and outside flange faces, said rotary valve face including said outside flange faces, said inside flange faces constituting fluid retaining faces to blank flow of fluid to and from said face wall valve means, said external flange body means having external fluid conduction wall means communicatingly interconnecting said inside and outside external flange faces, said internal flange body meanshaving internal fluid conduction wall means communicatingly interconnecting said inside and outside internal flange faces, said external and internal fluid conduction wall means communicatingly registering with said fluid port means in said face wall valve means.

Other objects and a fuller understanding of this invention may be had by referring to the following description and claims, taken in conjunction with the accompanying drawings, in which:

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a top plan view of my fluid pressure device;

FIG. 2 is a left-hand end view of my fluid pressure device and shows principally the end mounting flange;

FIG. 3 is a longitudinal sectional view of FIG. 1, taken through the vertical center thereof, except that the section through the valve means is taken along the line 23-24 of FIG. 20;

FIG. 4 is an enlarged fragmentary cross-sectional view of the bearing fixation means in FIG. 3 to accommodate for axial tolerance in matching the position of the bearing in the bore of the housing, the view showing the position of the parts before engagement of the fixation means;

FIG. 5 is a view similar to FIG. 4, but shows the position of the parts after engagement of the fixation means;

FIG. 6 is a view of the right-hand end of FIG. 3;

FIG. 7 is a view taken along the line 7-7 of FIG. 3, showing the stator-rotor mechanism;

FIG. 8 is a view taken along the line 8-8 of FIG. 3, showing the side of the stationary valve member, next adjacent to the stator-rotor mechanism:

FIG. 9 is a view showing the opposite side of the stationary valve, next adjacent the rotary valve;

FIG. 10 is a vertical cross-sectional view of a bushing which separates the hollow housing into a left-hand end compartment and a right-hand end compartment, including an abutment sleeve for securing the bushing in place;

FIG. 11 is a view taken along the line l111 of FIG. 3, with the rotary valve being omitted, the view being principally a right-hand end view of the hollow housing showing the bushing and the abutment sleeve mounted therein, the view also including a cross-section of the actuating shaft with the square portion thereof shown in a timed relation with respect to the position of the stator-rotor mechanism in FIG. 7;

FIG. 12 is a right-hand end view of the wear face only of the rotary valve and is shown in a timed relation with respect to the position of the stator-rotor mechanism in FIG. 7;

FIG. 13 is a left-hand end view of the wear face only of the rotary valve and is shown in a timed relation with respect to the position of the stator-rotor mechanism in FIG. 7;

FIG. 14 isa left-hand end view of the rotary valve, showing a torque-transmitting member mounted therein and comprising an open annular ring;

FIG. 15 is a flat side view of the torque-transmitting member shown in FIG. 14;

FIG. 16 is an edge view of the torque-transmitting member shown in FIG. 15; 1

FIG. 17 is a left-hand end view of the rotary valve, showing a modified torque-transmitting member comprising a closed annular ring;

FIG. 18 is a flat side view of the torque-transmitting member shown in FIG. 17;

FIG. 19 is an edge view of the torque-transmitting member shown in FIG. 18;

FIG. 20 is a view of the rotary valve, looking at the right-hand end thereof; and shows the rotary valve in timed relation with respect to the position of the statorrotor mechanism in FIG. 7;

FIG. .21 is a view of the rotary valve, looking at the left-hand end thereof, and shows the rotary valve in timed relation with respect to the position of the statorrotor mechanism in FIG. 7;

FIG. 22 is a cross-section of the rotary valve taken along the line 22-22 of FIG. 20;

FIG. 23 is a cross-section of the rotary valve, taken along the line 2323 of FIG. 20;

FIG. 24 is a cross-section of the rotary valve, taken along the line 24-24 of FIG.

FIG. 25 is a view of a modified left-hand end of the rotary valve, showing a cam finger extending from the actuating shaft for rotating the rotary valve once for each rotation of the actuating shaft;

FIG. 26 is a view similar to FIG. 25, but shows a double cam finger spaced from the opposed substantially parallel side wall means between which the cam finger slidable engages;

FIG. 27 is a fragmentary view of the actuating shaft with the cam-finger extending therefrom;

FIG. 28 is a view of a modified left-hand end of the rotary valve, showing an eccentric cam wall means;

FIG, 29 is an end view of the actuating shaft having a concentric cam integrally provided thereon, the concentric cam being disposed to be rotatively mounted in the eccentric cam wall means in FIG. 28 when the actuating shaft is orbitally mounted;

FIG. 30 is a fragmentary side view of the actuating shaft and concentric cam in FIG. 29; and

FIG. 31 is a view similar to FIG. 29, but shows the concentric cam separately and non-rotatively mounted on the actuating shaft.

DESCRIPTION OF THE PREFERRED EMBODIMENT My invention may comprise a fluid motor, a fluid pump, a fluid transmission, a fluid servomotor and/or any other related device.

The fluid pressure operating means may be of the type usually referred to in the trade as a stator-rotor orbital mechanism.

In this application, the term stator" and rotor are not used in a limited sense. The term stator is applied to the element which has a fixed axis and the term rotor is applied to the element which has a movable axis characterized in that said rotor is disposed for rotational movement about its own movable axis and for orbital movement about the fixed axis of the stator. Thus, in this application, the outer surrounding element, usually referred to as the stator, may be either the stator or the rotor, depending upon whether it has a fixed axis or a movable axis and the inner element, usually referred to as the rotor, may be either the rotor or the stator depending upon whether it has a movable axis or a fixed axis.

The valve system of my invention constitutes an improvement over the prior art and involves a new separate valve means for commutatively directing the flow of fluid to and from the stator rotor mechanism.

7 For clarity of the invention, the usual shaft and static seals are not shown. Also, all wear parts are made of vhardenable or bearing metal and are well lubricated by the operating fluid.

With reference to the drawing, my invention comprises generally a main housing 20 having substantially a square cross-section. A mounting flange 21 is secured to the left-hand end of the housing by screws 26. The housing 20 is hollow from end-to-end, and intermediate the ends of the hollow housing, there is provided a bushing 22 which generally separates the hollow housing into a left-hand end compartment and a right-hand end compartment. Rotatively mounted in the left-hand end compartment is a main shaft 25 having an axis substantially coinciding with the fixed axis. A rotary valve 28 is mounted in the right-hand end compartment and is adopted for rotational movement about the fixed axis. On the right-hand end ofthe hollow housing, there is mounted a square stationary valve member 29 by means of screws 30. Attached to the right-hand face of the stationary valve member 29, is a stator-rotor mechanism 31 comprising a stator element 32 and a rotor element 33. An end cap 34 encloses the statorrotor mechanism. The stator-rotor mechanism 31 and the end cap 34 are secured to the stationary valve member 29 by means of screw 35.

The valve system, which comprises the stationary valve member 29 and the rotary valve member 28, is independently mounted between the main shaft 25 and the stator-rotor mechanism 31, and thus the rotary valve 28 is free from both the radial thrust and the end thrust to which the main shaft may be subjected. The rotary valve 28 is adapted to be rotated about the fixed axis relative to the stationary valve member by universal drive means, indicated by the dotted line 40 and includes an intermediate shaft portion 38 of an actuating shaft 39 which drivingly interconnects the rotor element 33 to the right-hand end of the main shaft 25. The universal drive means may embody rotational phasing, as will be explained later.

The main shaft 25 comprises an enlarged internal portion having a reduced external portion 41 extending axially outwardly of the main housing 20 through the mounting flange 21. The enlarged internal portion of the main shaft is supported preferably by tapered roller bearings 42 and 43, respectively, having inner cones 44 and 45 and outer cups 46 and 47. The tapered roller bearings are disposed side-by-side with the bearing 42 disposed oppositely to that of the tapered roller bearing 43. Thus, the tapered roller bearings 42 and 43, in combination with each other, provide for radial thrust as well as for end thrust in both axial directions, with the tapered roller bearing 42 disposed to take the greater part of the radial load. The enlarged internal portion of the main shaft 25 is provided with a first portion 50 upon which the inner cone 45 is pressed and a second portion 51 upon which the inner cone 44 is pressed. The portion 50 terminates into a shoulder 52 against which the right-hand end of the inner cone 45 abuts. The two inner ends of the cones 44 and 45 are separated by a shaft spacer ring 53. Mounted against the left-hand end of the inner cone 44 is a tightening nut 54 which threadably engages male threads 55 provided on a reduced stepped portion of the shaft. Upon tightening the nut 54, the two tapered roller bearings 42 and 43 are securely mounted upon the main shaft. The tightening nut 54 may be provided with a built-in locking feature to prevent loosening.

The internal surface of the left-hand end compartment of the hollow housing 20 is provided with a first bore portion 56 into which the outer cup 47 is pressed and a second bore portion 57 into which the outer cup 46 is pressed. The bore portion 56 terminates into a shoulder 58 against which the right-hand end of outer cup 47 abuts. The two inner ends of the cups 46 and 47 are separated by a bore spacer ring 59. As shown in FIGS. 3, 4 and 5, the outer cup 46 is secured against axial movement to the left by axial fixation means, indicated by the reference character 60. The axial fixation means 60 comprises an annular V-shaped or pointed rib which axially abuts against the outer cup 46. The rib may be provided on theprojecting end of a cylindrical body 61 constructed integrally with the flange 21. By pressing the flange 21 against the end of the housing 20, the pointed rib is coined against the outer cup 46, with the result that the fixation means accommodates for axial tolerance in matching the position of the cup 46 in the bore of the housing 20. The pressure required to coin the axial fixation means is greater than the end-wise thrust load to which the hearing means 42 may be subjected in operation, in which case the outer cup 46 is resisted against axial movement to the left. In assembly, the axial fixation means is axially fixable (coinable) and is disposed to resist an axial thrust load greater than the axial thrust load to which the bearing means 42 may be subjected in operation. The FIG. 4 shows the axial fixation means 60 before it is coined or fixed and the FIG. 5 shows the axial fixation means after it has been coined. The main shaft is entirely supported by the two tapered roller bearings 42 and 43. The reduced external shaft portion 41 where it passes axially through the end mounting flange 21 is not journalled therein but rotates therein with a small radial clearance which is adapted to be sealed off by suitable shaft seal means, not shown. The tapered roller bearing assembly is claimed to be new and novel to the extent that the respective inner cones and the respective outer cups are spaced apart by spacer rings, with the inner cones held against axial movement on the shaft by a tightening nut and with the outer cups held against axial movement in the housing by axial fixation means. With my bearing assembly, the external shaft portion 41 is disposed to withstand a heavy load.

' The main housing is provided with first and second fluid ports 23 and 24. When operated as a fluid motor, the first fluid port 23 constitutes an inlet or high pressure port and the second fluid port 24 constitutes an outlet port or low pressure.

In the description, my device will be described as a fluid motor, but it is understood that it may be utilized for any other related purpose, particularly as a pump.

As illustrated in FIG. 7, the stator element 32 has seven internal teeth which defines the outer wall of a fluid compartment. The rotor element 33 has six external teeth, one less than that of the stator element. The stator element may be described as having (n) number of internal teeth, and the rotor element may be described as having (n-l) number of external teeth. The stator element has a center 69, usually referred to as the fixed or stationary axis since the stator element is stationarily mounted and does not rotate. in this application and claims, the expression fixed stator axis or simply fixed axis, includes not only the fixed axis of the stator, but also any axis which coincides, or is in axial alignment therewith.

The rotor 33 has a movable axis, identified by the reference character 70, and is radially spaced from and moves in an orbital path about the fixed axis 69 of the stator. The orbital path of the movable axis 70 is a true circle with its center coinciding with the fixed axis of the stator. The diameter of the true-circle, orbital path, is equal to the difference in the radial dimension between the crest contour and the root contour of a stator tooth. Upon relative movement between the rotor and the stator, the movable axis 70 of the rotor orbits in a true circle about the fixed axis of the stator. As the rotor moves within the stator, the inter-meshing teeth of the rotor and stator divide the fluid compartment confined therebetween into high and low pressure chambers along a revolving divisional line passing substantially diametrically through the fixed axis of the stator. For the position in FIG. 7, the divisional line is substantially diametrically vertical. For the position shown in FIG. 7, the divisional line may be more properly described as a divisional tapering band rather than a line and comprises substantially a slender triangle having an apex at the point where the top rotor tooth in FIG. 7 touches or contacts the arcuate surface of the stator contour and having a base defined by the distance between the sealing contact engagement on opposite sides of the bottom rotor tooth when fitting full-depth into the bottom stator tooth. To rotate the rotor 33 in a clockwise direction, the chambers on the left-hand side of the revolving divisional line or tapering band become high pressure chambers and the chambers on the right-hand side become low pressure chambers. The high and low pressure chambers alternately expand and contact as the rotor and stator move relative to each other. The divisional line or tapering band continually revolves in a counterclockwise direction as the rotor rotates in a clockwise direction within the stator.

As shown in FIG. 3, the actuating shaft 39 has a right-hand end portion provided with male spline teeth 71 which fit within female spline teeth 72 in the rotor, being referred to herein as first connection means. Thus, the right-hand end portion of the actuating shaft 39 is disposed for rotational movement about its own movable axis and for orbital movement about the fixed axis of the stator. The connection means between the lefthand end portion of the actuating shaft 39 and the main shaft 25, herein referred to as second connection means, also comprises male spline teeth 73 on the actuating shaft 39 which fit within female spline teeth 74 in the central core of the main shaft 25. The left-hand end portion of the actuating shaft, that is the second connection means, is disposed for rotational movement only about the fixed axis of the stator. The male spline teeth 71 and 73 constitute self-bearing means which respectively support both ends of the actuating shaft 39 for rotation about the orbiting axis. The third connection means comprises the universal drive means indicated by the dotted line 40 and includes an intermediate square shaft portion 38 which is provided with a torque-transmitting member- 78 for engaging the rotary valve 28 for rotating same about the fixed axis once for each rotation of the actuating shaft, see FlGS. 14-19, inclusive. As illustrated, the intermediate square shaft portion 38 passes through an enlarged opening 76 in the rotary valve member 28 and is disposed for rotational movement therein about its own movable axis and orbital movement about the fixed axis. The orbital diameter which the movable axis described about the fixed axis at the intermediate shaft portion 38, is of course, less than the orbital diameter at the right-hand end portion of the actuating shaft. Thus, the shaft 39 has an axis extending at an angle to the fixed axis or valve axis. As illustrated, the shaft 39 extends through a centrally disposed opening in the stationary valve member 29 and interconnects the rotor 33 and the rotary valve member 28. The shaft axis describes generally the surface of a cone upon movement thereof with the cone having generally a base circle at the first connection means between the shaft and the rotor 33. The centrally disposed opening in the stationary valve member 29 is larger in diameter than the male spline teeth 71 and 73 and has substantially the same diameter as the internal opening 76 in the rotary valve member 28. The cross-wise dimension (diameter) of the centrally disposed opening in the stationary valve member 29 is larger than that of the shaft 39 extending therethrough by an amount at least equal to the crosswise dimension of the cone described therein. The female spline teeth at the first connection means constitute bearing support means for radially supporting the male spline teeth substantially concentrically within the rotor 33. The torque-transmitting member 78 comprises an open annular washer or member (substantially a C-shaped member) having a central opening or slot large enough to pass over and slidably engage the intermediate square shaft portion 38 of the actuating shaft 39. The torque-transmitting member 78 and the intermediate square shaft portion 38 respectively have first and second interengageable torque-transmitting wall means slidable with respect to each other in a first direction for transmitting torque therebetween. The torque-transmitting member 78 may slide on the square cross-section by an amount to accommodate for the orbital movement of the intermediate shaft portion 38. The outside of the open annular torque-transmitting washer or member 78 is provided with oppositely disposed contacting wall means 101 and 102 which slidably and respectively fit between two oppositely disposed parallel wall surfaces 103 and 104 in the rotating valve member 28. The opposed contacting wall means 101 and 102 may slide within the wall surfaces 103 and 104 by an amount to accommodate for the orbital movement of the intermediate shaft portion 38. The direction at which the torque-transmitting member slides with reference to the rotating valve is perpendicular to the direction at which the torque-transmitting member slides with reference to the intermediate square shaft portion 38. The rotary valve 28 is caused to be rotated once for each rotation of the intermediate shaft portion 38. The drive means thus described constitutes universal drive means and provides for rotating the rotary valve relative to the stationary valve once for each rotation of the actuating shaft 39. The operation of the rotary valve is independent of the load and thrust on the main shaft. The FIGS. 17, 18 and 19 show a closed annular torquetransmitting washer or member 105 which operates in substantially the same manner as the open annular torque-transmitting washer or member 78. The central opening in the closed-annular member 105 is large enough to pass over the male spline teeth on the end of the actuating shaft 39. The intermediate square shaft portion 38 may be slightly larger for the closed annular torque-transmitting member. In both the closed and open annular torque-transmitting members, the fluid may flow therethrough, as open spaces are needed to accommodate for the slidable movements and these open spaces are ample to accommodate for the flow of fluid therethrough. The internal wall surfaces 103 and 104 of the rotary valve 28 between which the torquetransmitting members 78 or 105 slidably operate are shown in FIG. 21. The FIG. 21 shows the wall surfaces 103 and 104 in a timed position with respect to the position of the stator-rotor mechanism in FIG. 7. The torque-transmitting members 78 or 105 provide for rotating the rotary valve once for each rotation of the actuating shaft.

In my invention, the valve system means, which comprises the rotary valve member 28 and the stationary valve member 29, is disposed to provide a first series of commutating fluid connection means between the first fluid port 23 and the expanding fluid chambers in the statorrotor mechanism and a second series of commutating fluid connection means between the contracting fluid chambers in the stator-rotor mechanism and the second fluid port 24. To this end, the stationary valve member 29 has seven fluid openings 79 communicating respectively with the spaces between the internal teeth of the stator element, see FIG. 8. The stationary valve member 29 has a stationary valve face 81 and the rotary valve member 28 has a rotary valve face 82 disposed to rotate against the stationary valve face and make a sealing engagement therewith. The seven fluid openings 79 in the stationary valve member terminate respectively in the stationary valve face 81 with the terminating fluid openings being identified by the reference characters and being disposed circumferentially about the fixed axis and spaced at annular intervals thereabout substantially 360ln from each other, where (n) equals 7, being the number of fluid openings 80 terminating in the stationary valve wear face 81, see FIG. 9. The first series of commutating connection means, comprising six in number, terminate respectively in the rotary valve wear face 82. These six commutating connection means (first series) preferably comprise six fluid slot means 83 respectively having a closed inner end portion and an open outer end portion in constant fluid communication with the first fluid port 23. The second series of commutating fluid connection means, likewise comprising six fluid slot means, are identified by the reference character 84 and respectively have a closed outer end portion and an open inner end portion in constant fluid communication with the second fluid port 24.

As shown, the stationary valve member 29 has a stationary flat sealing face (FIG. 8) on a side thereof opposite from the stationary valve face 81, and is disposed to be sealingly held in facing relation against the lefthand plane side of the stator 32 and the rotor 33. The centrally disposed opening in the stationary valve member 29 where it meets with the stationary flat sealing face has a boundry edge substantially concentric to said stator axis and defines with the stationary flat sealing face a concentric sealing profile boundry edge having a diameter greater than that of the shaft 39 therein by an amount at least equal to the cross-wise dimension of the cone described therein by the inclined axis of the shaft 39. The external teeth of the rotor 33 define a contour which has an orbiting profile edge slidably engaging the stationary flat sealing face and defines an orbiting slidable juncture therewith. The orbiting profile edge of the teeth thus define with the stationary flat sealing face an orbiting sealing profile juncture edge. The concentric sealing profile boundry edge is disposed radially within and at a radial sealing distance from the orbiting sealing profile juncture edge, whereby the sealing distance therebetween constitutes face sealing means for blocking fluid in the operating fluid chambers from flowing into the centrally disposed opening upon relative movement of the rotor 33 in the stator 32.

The terminating fluid openings 80 comprises generally an elongated oval and are-each defined by opposed side portions 85 and 86 with each side portion extending in substantially a radial direction with respect to the fixed. axis. The opposed side portions 85 and 86 for the respective fluid openings 80 have substantially the same fixed angle therebetween and define the circumferential width thereof. The first series of fluid slot means 83 are, generally, in the shape of a deep external V-slot, with each being defined by opposing side wall portions 89 and 90. As shown in FIG. 12, the side wall portions 89 and 90 extend in substantially a radial direction with respect to the fixed axis. The respective side wall portions 89 and 90 for the first series of fluid slot means 83 and the respective side wall portions 91 and 92 for the second series of fluid slot means 84 have substantially the same fixed angle therebetween and defines the circumferential width of the respective fluid slot means. The fixed angle for the respective fluid slot means is substantially the same as that for the terminating fluid openings 80 which means that the circumferentialwidth for the terminating fluid openings 80 and for the fluid slots 83 and 84 are all the same. The facing lands between the fluid slot means 83 and 84 have the same circumferential width as the fl'uid slot means themselves. Thus, in FIGS. 9 and 12, the circumferential width, that is the width measured in a circumferential direction from side-to-side is the same for all the terminating fluid openings 80, for all the inlet fluid slots 83 (first series), for all the exhaust fluid slots 84 (second series), and for all the facing lands between the fluid slots 83 and 84. The registration of the fluid slots 83 and 84 with the terminating openings 80 provides ample fluid flow to and from the stator-rotor mechanism without undue restriction.

The first and second series of fluid slot means 83 and 84 are alternately disposed with respect to each other and are circumferentially disposed relative to the fixed axis and spaced at annular intervals thereabout substantially 360/ 2(n-l) from each other, where (n) is the number of fluid openings 80 terminating in the stationary valve face. Thus, the fluid slot means are spaced at annular intervals substantially 30 from each other. As illustrated in FIG. 3, the bushing 22 has its outer circumference tightly pressed (fluid seal tight) into the hollow housing. The bushing 22 has a side wall surface constituting stationary face wall means 65 disposed substantially parallel to and spaced axially from the stationary valve face 81. The rotary member 28 is disposed between the stationary face wall means 65 and the stationary valve face 81 and has a left-hand rotary end face 66 sealingly engaging the stationary face wall means 65. The bushing 22 is axially secured in place by an abutment sleeve 67 which has an internal wall surface 68 surrounding and radially spaced from the rotary valve member 28 and defines therewith external annular fluid-line chamber means or a reservoir 75 which extends all the way around the external surface of the-rotary valve member 28. The first fluid port 23 is disposed substantially directly above and in substantiallyvertical alignment with the annular fluid-line reservoir 75. As illustrated in FIG. 11, a vertically extending duct 36 in the hollow body 20 connects the external fluid-line chamber means in constant fluid communication with the first fluid port 23. The righthand end of the external fluid-line chamber means 75 is in constant fluid communication with the six fluid slot means 83 of the first series, which means that the six fluid slot means 83 of the first series are respectively in constant fluid communication with the first fluid port 23. Thus, the external fluid-line chamber means 75 is at the entrance of the valve means to give improved valve operation. The left-hand end of the fluid-line chamber means 75 extends to the stationary wall face means 65 of the bushing 22. The external fluid-line chamber means or reservoir 75 may be referred to as an external fluid conducting channel.

The enlarged internal opening 76 in the rotary valve member 28, through which the actuating shaft 39 extends, is in constant fluid communication with the second fluid port 24. The path of the constant fluid communication is through a radially extending space 96 between the main shaft 25 and the left-hand side of the bushing 22, and thence through a vertically extending duct 37 which connects the radial space 96 with the secondfluid port 24, see FIG. 11. The inner-open end of the second series of fluid slots 84 are in constant fluid communication with the enlarged fluid opening 76 in the rotary valve member 28, which means that the six fluid slot means 84 of the second series are respectively in constant fluid communication with the second fluid port 24. Thus, the enlarged fluid opening 76 in the rotary valve member 28, together with the radial space 96 as well as the space around the main shaft 25 constitutes internal fluid-line chamber means or a reservoir 77 at the exit of the valve means to give improved valve operation. The internal fluid-line chamber means or reservoir 77 may be referred to as an internal fluid conducting channel.

In operation as a fluid motor, high pressure fluid from the high pressure port 23 commutatively flow through the first series of commutating fluid connection means 83 of the rotary valve into the fluid openings 80 of the stationary valve member 29 and thence into the expanding pressure fluid chambers in the stator-rotor mechanism and drives the rotor 33 in a clockwise rotational direction within the stator 32. As the rotor is driven, the exhaust fluid in the low pressure contracting chambers commutatively flows through the fluid openings 80 of the stationary valve 29 into the second series of fluid commutating connection means 84 of the rotary valve and thence to the low pressure port 24. As the rotor is driven by the high pressure fluid, it operates the main shaft 25 through the actuating shaft 39.

The registration of the fluid connection means provided by the rotating valve face 82 in sealing engagement with the stationary valve face 81 is such that there is a first series of commutating fluid connections between the high pressure port 23 and the expanding fluid chambers in the stator-rotor mechanism and a second series of commutating fluid connections between the contracting fluid chambers and the low pressure port 24. The rotating valve 28 is independent of any radial thrust or of any end thrust to which the main shaft 25 may be subjected. Also the rotating valve 28 is substantially free from any radial thrust or any end thrust due to fluid pressure acting thereupon. This balance results from the fact that the fluid pressure acts upon oppositional wall portions which may substantially cancel out each other. Thus, the fluid slot means 83, first series, have a back wall portion 87 extending between the respective side wall portions 89 and 90 thereof. This back wall portion 87 is axially spaced from the stationary valve face 81 and is exposed to fluid pressure tending to exert a separating axial force for separating the rotary valve face 82 from the stationary valve face 81. The fluid pressure acting upon the total area of these back wall portions 87 may be substantially off-set by the fluid pressure acting upon the external oppositional wall means 94 at the right-hand end of the rotary valve, see FIGS. 21-24. Similarly, the fluid slot means 84, second series, having a back wall portion 88 between the respective side wall portions 91 and 92 thereof. This back wall portion 88 is axially spaced from the stationary valve face 81 and is exposed to fluid pressure tending to exert a separating axial force for separating the rotary valve face 82 from the stationary valve face 81. The fluid pressure acting upon the total area of these back wall portions 88 may be substantially off-set by the fluid pressure acting upon the internal oppositional wall means 98 at the left-hand end of the rotary valve, see FIGS. 21-24. Thus, the axial fluid thrust may be substantially cancelled out. There is substantially no radial fluid thrust acting upon the rotary valve 28 since the fluid extends around the entire circumference thereof, as well as within the central opening thereof.

The right-hand end of the rotary valve 28 has, as shown in FIGS. 22, 23 and 24, a stepped, segmental circumferential rim section 99 constituting an external flange of a larger diameter than the remaining outer cylindrical surface of the valve which, in part, defines the external annular fluid -line chamber means 75. The lead line 94 points to an inside flange face for the external flange 99. In mounting the rotary valve in the abutment sleeve 67, it is preferable that the outer surface of the segmental circumferential rim section 99 be rotatively mounted as a bearing within the internal wall surface 68 of the abutment sleeve, whereby it functions as a self-bearing to support the rotary valve. The hollow annular body of the rotary valve 28 has an internal flange (best shown in FIG. 22) extending inwardly thereof. The lead line 98 points to an inside flange face for the internal flange. The outside flange faces for the external and interal flanges are provided by the rotary valve face 82.

As an object of the invention, the FIGS. 25, 26 and 27 show a further modification of the universal drive means embodying rotational phasing and comprises a cam actuating finger 95 extending from the actuating shaft 39. The actuating finger 95 is preferably integral with the actuating shaft and has two oppositely disposed cam-actuating contact portions 97 which respectively slide between two substantially parallel cam-follower wall means 100. The two contact portions 97 with respect to radial lines passing therethrough preferably define an included angle therebetween of approximately 90 degrees. As the actuating shaft 39 orbits, the contact portions 97 slide upand-down (piston fashion) relative to the parallel wall means 100. The action is such that the rotating valve 28 is rotated once for each rotation of the actuating shaft 39. In FIG. 25, the contact portions 97 of the cam finger make a relatively close sliding contact fit with the cam-follower wall means 100. The clearance is sufficient to permit orbiting of the actuating shaft. In operation there is a disposition for the rotary valve to have a circumferential rotational phasing with respect to the rotation of the actuating shaft 39. During certain portions of the orbit movement of the actuating shaft, the rotational phasing has the effect of subtracting from the rotation of the actuating shaft, with the result that the speed of rotation of the rotary valve is reduced. During other portions of the orbit movement, the rotational phasing has the effect of adding to the rotation of the actuating shaft, with the result that the speed of rotation of the rotary valve is increased. The rotational phasing makes a fresh start at the beginning of each orbit and terminates at the end of each orbit. The amount of the circumferential displacement resulting from the rotational phasing is a function of the radius of the orbital movement at the intermediate portion 38 of the actuating shaft. The rotational phasing has the effect of varying the timing of the rotary valve with respect to the movements of the rotor within the stator and produces a new valving action.

In FIG. 26, which shows two oppositely disposed finger cams, instead of one in FIG. 25, the clearance between the opposed cam contact portions 97 and the cam-follower wall means 100 is shown to be increased. The amount of the clearance on each side may be substantially equal to the radius of the orbital movement at the intermediate portion 38 of the actuating shaft. The action produced in FIG. 26 also gives rotational phasing and provides ample clearance to permit orbiting of the actuating shaft. The clearance spaces in FIG. 26 renders it unnecessary to have the laterally extending tips upon which the contact portions 97 are provided. The corner edges become the contact portions 97.

FIGS. 28, 29 and 30 and 31 show a further modification of the universal drive means and comprises eccentric wall means 106 in the rotary valve (see FIG. 28) into which is rotatively mounted a concentric cam 107 (see FIG. 29), when the actuating shaft'is in orbiting position. In operation, the orbiting movement of the ac- I tuating shaft causes the concentric cam 107 to become eccentric in movement within the eccentric wall means 106, with the result that the rotary valve is rotated once for each rotation of the shaft. In FIG. 29, the concentric cam 107 is shown integral with the actuating shaft. In FIG. 31, the concentric cam 108 is shown separate from the actuating shaft, but non-rotatively connected thereto by the illustrated gear teeth. The operation of the concentric cams 107 and 108 are substantially the same. The universal drive means as shown in this application provide for producing an action whereby the rotary valve is rotated once for each rotation of the actuating shaft, with the further provision that the construction shown in FIGS. 25, 26 and 27 embody an action which has been described as rotational phasing to provide a new valve action.

As shown in FIG. 24, the second series of fluid commutating connection means 84 (exhaust slots) are shown as extending from one end of the rotary valve to the other. The terminating ends for these exhaust slots 84 are shown in FIG. 21. For the sake of clarity, these terminating ends are not shown in FIGS. 25, 26 and 28.

The rotary valve 28, as shown in FIG. 20, represents a timed position with respect to the stationary valve shown in FIG. 9 and with respect to the stator-rotor mechanism shown in FIG. 7. As the rotary valve 28 in FIG. is rotated in a clockwise direction, the registration of the fluid slots 83 and 84 with the fluid openings 80 in the stationary valve 29, directs exhaust fluid to flow therefrom, causing the rotor 33 to rotate in a clockwise direction. All the universal drives disclosed herein are disposed to maintain this proper timed relationship between the actuating shaft 39 and the rotary valve 28 for rotating the rotary valve in its proper timed relationship with the stationary valve 29 and the statorrotor mechanism.

Although this invention has been described in its preferred form with a certain-degree of particularity, it is understood that the present disclosure of the preferred form has been made only by way of example and that numerous changes in the details of construction and the combination and arrangement of parts may be resorted to without departing from the spirit and the scope of the invention as hereinafter claimed.

What is claimed is:

1. One-piece rotary valve component means having a rotary valve face disposed to sealingly engage face wall valve means having communicating fluid port means therein, said rotary valve component means including hollow annular valve body means having a valve end portion, said hollow annular valve body means retaining fluid externally therearound and retaining fluid internally therewithin, said valve end portion having external flange body means extending outwardly of said hollow annular valve body means and internal flange body means extending inwardly of said hollow annular valve body means, said internal flange body means having a central opening extending therethrough said external and internal flange body means respectively having inside and outside flange faces, said rotary valve face including said outside flange faces, said inside flange faces constituting fluid retaining faces to blank flow of fluid to and from said face wall valve means, said external flange body means having external fluid conduction wall means communicatingly interconnecting said inside and outside external flange faces, said internal flange body means having internal fluid conduction wall means communicatingly interconnecting said inside and outside internal flange faces, said external and internal fluid conduction wall means communicatingly registering with said fluid port means in said face wall valve means.

2. The structure of claim 1, wherein said external flange body means has an external peripheral surface and wherein said internal flange body means has an internal peripheral surface, said external fluid conduction means comprising slots extending inwardly of said external peripheral surface, said internal fluid conduction means comprising slots extending outwardly of said internal peripheral surface.

3. The structure of claim 1, wherein said external flange body means has external lands between said external fluid conduction wall means and wherein said internal flange body means has internal lands between said internal fluid conduction wall means.

4. The structure of claim 1, wherein said external and internal fluid conduction means are circumferentially displaced with respect to each other.

5. The structure of claim 1, wherein said external and internal fluid conduction means being the same in number and each being one less than the number of said fluid port means.

6. The structure of claim 3, wherein said rotary valve component means has a rotary axis and is symmetrical with respect to said axis in each of first, second and third planes passing through said axis and respectively through said external fluid conduction wall means, through said internal fluid conduction wall means, and through said lands.

7. Valve means for fluid pressure means having orbital and rotary movements, said valve means including first valve means having first valve surface means and second valve means having second valve surface means, said first valve means having fluid port means extending from said first valve surface means to said fluid pressure means, and actuating means interconnecting said fluid pressure means and said second valve means for actuating said second valve surface means for valve movement relative to said first valve surface means to control the flow of fluid through said fluid port means to and from said fluid pressure means, said valve movement including a first movement in response to said rotary movement of said fluid pressure means and a second movement in response to said orbital movement of said fluid pressure means.

8. The structure of claim 7, wherein said first valve means is disposed between said fluid pressure means and said second valve means.

9. The structure of claim 7, wherein said fluid pressure means has side surface means, said first valve means having face surface means disposed in facing relation to said side surface means of said fluid pressure means, said face surface means and said valve surface means of said first valve means being substantially parallel to each other, said first valve means being disposed between said side surface means of said fluid pressure means and said second valve surface means. 

1. One-piece rotary valve component means having a rotary valve face disposed to sealingly engage face wall valve means having communicating fluid port means therein, said rotary valve component means including hollow annular valve body means having a valve end portion, said hollow annular valve body means retaining fluid externally therearound and retaining fluid internally therewithin, said valve end portion having external flange body means extending outwardly of said hollow annular valve body means and internal flange body means extending inwardly of said hollow annular valve body means, said internal flange body means having a central opening extending therethrough said external and internal flange body means respectively having inside and outside flange faces, said rotary valve face including said outside flange faces, said inside flange faces constituting fluid retaining faces to blank flow of fluid to and from said face wall valve means, said external flange body means having external fluid conduction wall means communicatingly interconnecting said inside and outside external flange faces, said internal flange body means having internal fluid conduction wall means communicatingly interconnecting said inside and outside internal flange faces, said external and internal fluid conduction wall means communicatingly registering with said fluid port means in said face wall valve means.
 1. One-piece rotary valve component means having a rotary valve face disposed to sealingly engage face wall valve means having communicating fluid port means therein, said rotary valve component means including hollow annular valve body means having a valve end portion, said hollow annular valve body means retaining fluid externally therearound and retaining fluid internally therewithin, said valve end portion having external flange body means extending outwardly of said hollow annular valve body means and internal flange body means extending inwardly of said hollow annular valve body means, said internal flange body means having a central opening extending therethrough said external and internal flange body means respectively having inside and outside flange faces, said rotary valve face including said outside flange faces, said inside flange faces constituting fluid retaining faces to blank flow of fluid to and from said face wall valve means, said external flange body means having external fluid conduction wall means communicatingly interconnecting said inside and outside external flange faces, said internal flange body means having internal fluid conduction wall means communicatingly interconnecting said inside and outside internal flange faces, said external and internal fluid conduction wall means communicatingly registering with said fluid port means in said face wall valve means.
 2. The structure of claim 1, wherein said external flange body means has an external peripheral surface and wherein said internal flange body means has an internal peripheral surface, said external fluid conduction means comprising slots extending inwardly of said external peripheral surface, said internal fluid conduction means comprising slots extending outwardly of said internal peripheral surface.
 3. The structure of claim 1, wherein said external flange body means has external lands between said external fluid conduction wall means and wherein said internal flange body means has internal lands between said internal fluid conduction wall means.
 4. The structure of claim 1, wherein said external and internal fluid conduction means are circumferentially displaced with respect to each other.
 5. The structure of claim 1, wherein said external and internal fluid conduction means being the same in number and each being one less than the number of said fluid port means.
 6. The structure of claim 3, wherein said rotary valve component means has a rotary axis and is symmetrical with respect to said axis in each of first, second and third planes passing through said axis and respectively through said external fluid conduction wall means, through said internal fluid conduction wall means, and through said lands.
 7. Valve means for fluid pressure means having orbital and rotary movements, said valve means including first valve means having first valve surface means and second valve means having second valve surface means, said first valve means having fluid port means extending from said first valve surface means to said fluid pressure means, and actuating means interconnecting said fluid pressure means and said second valve means for actuating said second valve surface means for valve movement relative to said first valve surface means to control the flow of fluid through said fluid port means to and from said fluid pressure means, said valve movement including a first movement in response to said rotary movement of said fluid pressure means and a second movement in response to said orbital movement of said fluid pressure means.
 8. The structure of claim 7, wherein said first valve means is disposed between said fluid pressure means and said second valve means. 